Wine Chemistry and Biochemistry

(Steven Felgate) #1

492 N. Terrier et al.


flavanol monomers with proteins follows the same order as their partition coeffi-


cients between octanol and water, meaning that it increases with hydrophobicity of


the phenolic compound (Poncet-Legrand et al. 2007). Phenolic oxidation, gener-


ating polymeric species, resulted in enhanced protein interactions as evidenced by


higher inhibition of enzymes (Guyot et al.1996a), or changes in casein adsorption


properties at the air/liquid interface (Sausse et al. 2003). As mentioned above, higher


molecular weight flavanols are also selectively precipitated out by proteins. More-


over, within gelatins (Maury et al. 2001) or glutens (Maury et al. 2003), smaller


molecular weight proteins appeared more selective than larger ones. The interaction


mechanism also depends on protein concentration. At low concentration, it occurs


in three stages as the polyphenol/protein ratio increases, as described above: sat-


uration of the interaction sites, formation of metastable colloids, and aggregation


leading to haze. At high protein concentration, direct bridging occurs, resulting in


lower aggregation and turbidity thresholds. Interactions of flavonols with proteins


(Dufour and Dangles 2005) as well as their adsorption on PVPP is much more effi-


cient with aglycones as the sugar residue on the glycosides weakens the driving


forces (Laborde et al. 2006). Finally, other parameters such as the solvent character-


istics, the presence of other solutes and the temperature influence protein/flavanol


association and the properties of resulting complexes. Thus the affinity between


tannins and PRPs is lower at higher temperatures (Charlton et al. 2002a). The


presence of polysaccharides prevents coprecipitation of tannins and proteins (Luck


et al. 1994; Cheynier et al. 2006). Ionic strength and pH affect proteins solubility.


Precipitation of tannin protein complexes is highest at the protein pHi as electro-
static repulsions are minimal (Calderon et al. 1968; Perez-Maldonado et al. 1995;


Charlton et al. 2002a; Kawamoto and Nakatsubo 1997). The effect of ionic strength


and ethanol content on the interactions of epigallocatechin gallate with a salivary


PRP was investigated (Pascal et al. 2006). Increasing the ionic strength with sodium


chloride or tartrate ions resulted in an increased stability of the aggregates, mean-


ing that aggregation was not driven by repulsive electrostatic interactions. In 12%


ethanol, the protein was not fully dissolved and aggregation with epigallocatechin


gallate required much higher concentrations of the latter, confirming the role of


hydrophobic interactions.


9B.4.3.2 Interactionswith Polysaccharides


Actors


Major wine polysaccharides, including mannoproteins originating from yeasts and


plant cell wall constituents (e.g. arabinogalactan proteins (AGP) and rhamnogalac-


turonan II (RGII)), have been shown to interact with flavanols (Riou et al. 2002).


Besides, arabic gum (a mixture of arabinogalactans and arabinogalactan proteins)


can be added as a protecting colloid to limit or prevent aggregation, flocculation and


precipitation of tannins and tannin-protein complexes (Pellerin and Cabanis 1998).

Free download pdf